DE102004032026A1 - Heat sink, in particular for the walls of the upper furnace of an electric arc furnace or a shaft furnace - Google Patents

Abstract

Cooling body (1) comprises a layer of copper or copper alloy on the hot side (2) to which a plate (9) or frame plate (9a) made from copper or copper alloy is assigned. The plate or frame plate is closed using an elastic seal (10). A number of parallel longitudinal profiles (4a) are provided either in the plate or frame plate or in the seal as cooling channels. The plate or frame plate is connected to a covering plate (12) made from iron or steel material and forming the cold side (6).

Description

The The invention relates to a heat sink, in particular for the Walls of the Oven of an electric arc furnace or a shaft furnace, the hot one furnace atmosphere exposed, with one on the hot side, the heat transfer forming layer of copper or copper alloy and on the cold side from trough-shaped Products formed cooling channels, through the coolants guided are on the cold side to a coolant supply and a coolant discharge are connected.

such Replace heat sink from about the mid-70s the formerly common ff-lining and form Wall elements in box shape with coolant baffles inside and with various forms of slag holders at the Hot side.

Later were boxy Wall elements replaced by pipe structures. Here were the pipes arranged in a so-called pipe-on-pipe construction vertically, however after a short time was generally replaced by a horizontal arrangement. These Construction had the advantage of mechanical stability, but also the disadvantages high pressure losses and the need to install slag holders, which have only a limited life and often the Starting point for Cracks in the pipes formed.

since Around 1990, a specialist company builds its wall elements in the so-called pipe-gap-pipe construction. The pipes lie horizontally and the flow reversals are formed by cast pipe bends. These wall elements have no Schlakkenhalter, because the ff-spray material in the gaps between the pipes can hold firmly. Furthermore the pressure loss in this type of wall elements is considerably lower.

Such the hot ones furnace atmosphere exposed wall elements have only a limited life and are common of damage affected. The damages can be divided into cracks on the pipe surface, damage by scrap impact (at Charging an electric arc furnace) Damage caused by arcing and spark erosion, damage through oxygen and damage on back plates.

insofar If the heat sinks described at the beginning are more advantageous, which are also used as wall panels in blast furnaces can be used.

The initially designated heat sink is from the DE 100 00 987 A1 known. However, this heat sink is made of a forged or rolled ingot of copper and the cooling channels are formed by trough-shaped rolled products. Apart from this training, the raw block made of copper or copper alloy is uneconomical in view of its material costs. The constantly increasing performance requirements lead to increasing heat loads of the cooling plates, which are stressed by tensile stresses on the inside and on the outer wall by compressive stresses. If the material-specific stress limits are exceeded, the material is plastically deformed, causing cracks and, in severe cases, damage to the heat sink.

From the DE 29 07 511 C2 is a likewise made entirely of copper or a copper alloy heat sink with vertical blind holes produced by mechanical deep drilling. The material costs and processing are correspondingly uneconomical.

Of the Invention is based on the object, a claimable design with economical cost To produce manufacturable components, while copper or copper alloy to save and to achieve a long service life.

The Asked object is inventively achieved in that one of the hot side assigned, determined in its thickness plate or frame plate made of copper or copper alloy, by means of a permanently elastic Seal is closed, with a variety of trough-shaped, parallel juxtaposed longitudinal profiles either in the Thickness of the plate or the frame plate or in the permanently elastic Seal provided as cooling channels and that the plate or frame plate is made with one of iron or steel materials existing, the cold side forming cover plate tight is connectable. As a result, only a small proportion of the material Copper or copper alloy needed and the much less stressed part on the cold side can be cost effective Material are produced. The variety of trough-shaped longitudinal profiles causes a planar more uniform discharge the heat to the cooling medium. The load capacity of the heatsink is total higher.

In Embodiment of the invention, the elastic seal is made thermally conductive Plastic, heat-resistant rubber or from a metal membrane. The seal limits the cooling channel according to the invention or more cooling channels and will thereby by means of the coolant even cooled. Out For this reason, there is a protection against heat stress, so that such elastic materials can be used permanently.

A Further development is that the ratio of the wall thicknesses of the cover plate to the plate of copper or copper alloy equal to or smaller 1 is.

A relatively thin Cover plate or a correspondingly claimable cover plate is created in that the cover plate is reinforced by means of outwardly projecting ribs.

Further Characteristics are given by the fact that the cover plate with the plate or the frame plate made of copper or a copper alloy on the outer circumference welded are.

A Another improvement of the invention is achieved in that the permanently elastic seal is provided by ribs, that of the plate or the frame plate made of copper or a copper alloy facing, the cooling channels from the long profiles form. This allows the seal itself to be stiffened and the elasticity the seal is permanently retained.

The Cooling channels in the Cover plate and / or the seal can as ribs in cross section a Triangular shape, form a semicircular shape or a trapezoidal shape. in the general are here polygonal or round cross-sectional or cross-sectional mixing forms advantageous.

there can advantageously made a further embodiment such be that either the cavity within the triangular shape, the semicircular shape or the trapezoidal form the cooling channels or the adjoining rooms between two ribs.

In the drawing are embodiments of Invention, which are explained in more detail below.

It demonstrate:

1 a vertical cross section through a stationary heat sink,

2A a cross section through the heat sink in front of the plane of the seal as a first embodiment with triangular in cross-section long profiles,

2 B the too 2A Belonging top view of the seal in the in 2A designated cutting plane AB,

3A a cross section like 2A as a second alternative embodiment with triangular in cross section, hollow cooling channels

3B the too 3A belonging top view of the seal

4A a cross section like 2A as a third alternative embodiment with semi-circular in cross-section full long profiles

4B the too 4A belonging top view of the seal,

5A a cross section like 2A as a fourth alternative embodiment with trapezoidal in cross-section hollow long profiles and

5B the too 5A belonging top view in the designated section plane.

According to 1 is the heat sink 1 shown vertically. But it can also be installed horizontally or diagonally. On the hot side 2 (right) is the layer 3 made of copper or copper alloy. Internally 3a is a variety of individual cooling channels 4 with smaller flow cross sections for a coolant 5 formed, which usually consists of water. With a large number of cooling channels, these are made of long profiles 4a ( 2A - 5B ) educated. The long profiles 4a are on the cold side 6 (left), on which also a coolant supply line 7 and a coolant drain 8th connected are the coolant 5 lead in the circulation.

The on the hot side 2 lying plate 9 as a frame plate 9a is executed, forms the heat transfer between the hot atmosphere of the arc furnace or the shaft furnace and is therefore made of copper or a copper alloy out. The plate 9 or the frame plate 9a transfers the heat to the individual cooling channels 4 from the large number of trough-shaped, parallel juxtaposed long profiles 4a consist.

It can serve as a cooling channel 4 either a cavity 19 ( 3A ) of the long profile 4a or one by two adjacent long profiles 4a educated adjoining room 20 be used as flow channels.

The plate 9 or the frame plate 9a be through a permanently elastic seal 10 closed, being on the cold side 6 one made of iron or steel materials 11 existing cover plate 12 stuck with the plate 9 or the frame plate 9a for example, on the outer circumference 9b by welding or as drawn by means of screws 12a are connected. The ratio of wall thicknesses of the cover plate 12 to the plate 9 or frame plate 9a made of copper or copper alloy is equal to or less than 1.0.

The permanently elastic seal 10 consists of thermally conductive plastic, heat-resistant rubber or a metal diaphragm.

For stiffening and attachment, the cover plate 12 ( 1 ) by means of outwardly projecting ribs 13 be strengthened. On the hot side 2 usually (unspecified) grooves are provided, if necessary. After completion of the assembly, the application of refractory ramming or spraying masses when using the heat sink 1 facilitate in a shaft furnace or when using the heat sink 1 for an electric arc furnace to intercept the inevitable melting spatters.

In the 2A is out of the shift 3 made of copper or copper alloy on the hot side 2 the plate 9 or the frame plate 9a visible, as well as the permanently elastic seal 10 in a first embodiment, a plurality of cooling channels 15 forms ( 2 B ), each between two cross-sectional triangular shapes 16 arise. The permanently elastic seal 10 is about as a "mat" made in one piece and is easy in the frame plate 9a inserted and by means of the cover plate 12 locked. In the event that the cooling channels 15 in the plate 9 or the frame plate 9a are provided, the permanently elastic sealing 10 also be smooth and flat.

In the 3A is a second alternative embodiment of the heat sink 1 shown, being on the hot side 2 within the shift 3 made of copper or copper alloy in the form of the frame plate 9a a recess is provided, in turn, as a mat, the permanently elastic seal 10 with a variety of long products 4a inserted and by means of the cover plate 12 made of iron or steel materials 11 and screws 12 is attached. This embodiment sees hollow longitudinal profiles 4a before, so that between each two longitudinal profiles 4a Coolant through an adjoining room 20 forward and through the cavity 19 the long profiles 4a can flow back.

According to 4A are longitudinal profiles 4a in the recess of the frame plate 9a with a semicircular shape 17 in cross-section and form between two long profiles 4a a cooling channel 15 , The long profiles 4a form over connecting webs turn the permanently elastic seal as a mat. In 4B are the bases of the flow channels 15 seen.

A fourth alternative comes from the 5A and 5B Out: The long profiles 4a have trapezoidal shape 18 in cross section, again between each two long profiles 4a a cooling channel 15 for the fore and the inside of the trapezoidal shape 18 for the return of the coolant (or vice versa) can be connected.

In all embodiments, a flat, rectangular and compact heat sink is formed 1 , which takes up little space and is easy to install.

1

heatsink

2

hot side

3

layer made of copper or copper alloy

3a

Interior of the heat sink

4

cooling channel

4a

long profile

5

coolant

6

cold side

7

Coolant feed line

8th

coolant derivation

9

plate made of copper or copper alloy

9a

frame plate

9b

outer periphery

10

elastic seal

11

Iron- or steel material

12

cover

12a

screw

13

ribs on the cover plate

14

ribs on the elastic seal

15

cooling channel

16

triangular shape

17

Semicircular shape

18

trapezoidal shape

19

cavity

20

Outbuildings

Claims (8)

Heat sink ( 1 ), in particular for the walls of the top furnace of an electric arc furnace or a shaft furnace which is exposed to the hot Ofenatmoshäre, with one on the hot side ( 2 ) the heat transfer layer ( 3 ) made of copper or copper alloy and on the cold side ( 6 ) cooling channels formed from trough-shaped products ( 4 ), by the coolant ( 5 ) and those on the cold side ( 6 ) to a coolant supply line ( 7 ) and a coolant discharge ( 8th ) are connected, characterized in that one of the hot side ( 2 ) assigned, in its thickness determinable plate ( 9 ) or frame plate ( 9a ) made of copper or copper alloy by means of a permanently elastic seal ( 10 ) is closed, wherein a plurality of trough-shaped, parallel, juxtaposed longitudinal profiles ( 4a ) either in the thickness of the plate ( 9 ) or the frame plate ( 9a ) or in the permanently elastic seal ( 10 ) as cooling channels ( 4 ) are provided and that the plate ( 9 ) or the frame plate ( 9a ) with one of iron or steel materials ( 11 ), the cold side ( 6 ) forming cover plate ( 12 ) is tightly connected. Cooling plate according to claim 1, characterized in that the permanently elastic sealing ( 10 ) consists of thermally conductive plastic, heat-resistant rubber or a metal diaphragm. Cooling plate according to one of claims 1 and 2, characterized in that the ratio of the wall thicknesses of the cover plate ( 12 ) to the plate ( 9 ) of copper or copper alloy is equal to or less than 1. Cooling plate according to one of claims 1 to 3, characterized in that the cover plate ( 12 ) by means of outwardly projecting ribs ( 13 ) is reinforced. Cooling plate according to one of claims 1 to 4, characterized in that the cover plate ( 12 ) with the plate ( 9 ) or the frame plate ( 9b ) made of copper or a copper alloy on the outer circumference ( 9b ) is welded. Cooling plate according to one of claims 1 to 5, characterized in that the elastic seal ( 10 ) by means of ribs ( 14 ) provided to the plate ( 9 ) or the frame plate ( 9b ), the cooling channels ( 15 ) from the longitudinal profiles ( 4a ) form. Cooling plate according to claim 6, characterized in that the ribs ( 14 ) in cross-section a triangular shape ( 16 ), a semicircular shape ( 17 ) or a trapezoidal shape ( 18 ) form. Cooling plate according to claim 6, characterized in that either the cavity ( 19 ) within the triangle shape ( 16 ), the semicircular shape ( 17 ) or the trapezoidal shape ( 18 ) the cooling channels ( 15 ) or each between two ribs ( 14 ) ancillary rooms ( 20 ).